Phenoxyacetic acid derivatives

ABSTRACT

4 (FURYL KETO), (2-THIENYL KETO) OR 2(5 METHYL THIENYL KETO), 2,3 DICHLORO PHENOXYACETIC ACIDS, THEIR ALKALI METAL SALTS AND PHARMACEUTICALLY ACCEPTABLE BASE ADDITION SALTS, ARE VALUABLE AS STRONG DIURETICS.

United States Patent Office 3,758,506 Patented Sept. 11, 1973 3,758,506 PHENOXYACETIC ACID DERIVATIVES Jean Jacques Godfroid, Noisy-le-Sec, and Jean Eugene Thuillier, Paris, France, assignors to C.E.R.P.H.A. (Centre Europeen de Recherches Pharmacologiques), Arcueil, Val-de-Marne, France No Drawing. Filed Oct. 7, 1970, Ser. No. 78,976 Claims priority, application France, Oct. 10, 1969, 6934760 Int. Cl. A611: 27/00; C07d 63/12 U.S. Cl. 260-332.2 A Claims ABSTRACT OF THE DISCLOSURE 4 (2-furyl keto), (2 thienyl keto) or 2(5 methyl thienyl keto), 2,3 dichloro phenoxyacetic acids, their alkali metal salts and pharmaceutically acceptable base addition salts, are valuable as strong diuretics.

This invention relates to new phenoxyacetic acid derivatives.

According to the present invention there is provided a phenoxyacetic acid of the general formula wherein R signifies 2-furyl keto, Z-thienyl keto, or 2(5- methyl thienyl) keto, an alkali metal salt of a said acid, or an addition salt of a said acid with a pharmaceutically acceptable base.

Of particular value as pharmaceutically acceptable bases are piperazine, N-methyl piperazine and N-methyl glucamine.

To prepare the new compounds, one of the esters may be saponified which is obtained by condensing with an ester of a haloacetic acid, particularly with ethyl chloracetate, the Z-furyl, 2-thienyl or Z-(S-methyl thienyl) 2,3- dichloro hydroxyphenyl ketone resulting from the condensation of 2,3-dichloro-anisole with the chloride of furan 2-carboxylic acid, thiophene-Z-carboxylic acid or of aluminium chloride, and then demethylating the ketophenolic ether so formed by the action of aluminium chloride. The phenoxyacetic acid is then freed from its salt by reaction with strong acid.

The reaction between the dichloroanisole and the acid chloride can be carried out in solvents such as carbon disulphide or methylene chloride, or even without a solvent. The methoxy phenyl ketone obtained can be demethylated, for example by the action of aluminium chloride in a solvent such as benzene or methylene chloride.

Instead of reacting an ester of a halogenoacetic acid with a ketophenol, the sodium salt of this phenol may be prepared by the action of sodium or potassium hydroxide, and condensing the salt with, for example, sodium or potassium monoehloracetate in an aqueous or alcoholic medium.

The following examples will serve to illustrate the invention. Temperatures are given in degrees centigrade. Melting points were determined by the Kofler block method unless otherwise stated.

EXAMPLE 1 4-(2-furyl keto) 2,3-dichloro phenoxy acetic acid (CE 3598) (a) To a solution of 44.2 g. of 2,3-dichloro-anisole (0.25 mole), 65 g. of furan Z-carboxylic acid chloride (0.5 mole) and 250 ml. carbon disulphide, there was added, in small portions, 66.6 g. (0.5 mole) of anhydrous aluminium chloride. The temperature during the addition was kept at 25. The mixture was then stirred at ambient temperature for 5 hours. The mixture was left overnight and then heated for 1 hour at 55 (reflux of carbon disulphide). The mixture was cooled, and the solution then hydrolised with 500 ml. of crushed ice containing 50 ml. of concentrated hydrochloric acid. The precipitate formed is dried and washed with a 30% solution of caustic soda, and then with distilled water. 64.7 g. of grey crystals were obtained, M. Pt. 148. Recrystallisation in methyl ethyl ketone gave 57.8 g. of crystals (yield melting at 150.

(b) To a solution of 40.6 g. (i.e. 0.15 mole) of the product just obtained in 350 ml. dethiophenated benzene, there was added, in small portions, 60 g. of anhydrous aluminum chloride. The mixture was then placed under reflux for two hours. The solution was hydrolized with 400 g. of ice. The precipitate formed is extracted and taken up in a 10% solution of sodium hydroxide, then reprecipitated in a 10% hydrochloric acid solution. There was thus obtained 34.8 g. of crystals which were recrystallised in 200 ml. benzene. 29.1 g. of crystals were obtained (yield 75%) melting at 129-130.

(c) A solution of sodium ethylate is prepared by dissolving 1.50 g. of sodium in 100 ml. absolute ethanol. There was then added 16.7 g. phenol (0.065 mole) and then 9.6 g. of ethyl chloracetate. The solution was refluxed for 14 hours. Extraction was carried out hot (elimination of sodium chloride) the crystals precipitating during cooling of the filtrate. There were collected 15 g. of crystals (yield of crude product 67%). After recrystallisation in isopropanol, 12.9 g. (58%) was obtained, melting at (d) 10 g. of the preceding ester were dissolved in the hot in 300 m1. of ethanol at 4 ml. of 30% caustic soda were added. A copious white precipitate formed. The mixture was refluxed for 30 minutes. The crystals were extracted and washed with hot alcohol. They were dissolved in ml. hot water and the acid precipitated with hydrochloric acid. Recrystallisation in 15 ml. 50% ethanol gave 8.6 g. of crystals (yield 95%) melting at 176. The sodium salt could be purified directly by recrystallisation in water (7 g. per 75 ml. water). Melting point 260-265 (Maquenne block, without correction).

EXAMPLE 2 4-(2-thienyl keto) 2,3-dichlorophenoxy acetic acid (CE 3624) (a) To a solution of 55 g. of 2,3-dichloroanisole (0.31) mole), 91 g. of thiophene 2-carboxylic acid chloride (0.62 mole) and 180 ml. carbon disulphide, there was added little by little 82.7 g. of anhydrous aluminium chloride, keeping the temperature at about 25 The reaction mixture was stirred at ambient temperature for five hours, left standing overnight and then heated for one hour at 55. The solution was cooled and hydrolised by 250 g. of ice and 60 ml. concentrated hydrochloric acid. The precipitate formed is treated with a 30% solution of caustic soda, then washed with water. After recrystallisation in 95% ethanol, 88.6 g. (yield 92%) of crystals are obtained melting at 108.

The process can alo be carried out without solvent keeping the seame proportions of reactants, or in methylene chloride by adding a slight excess of aluminium chloride powder to a solution of one mole of dichloroanisole and one mole of acid chloride.

(b) 88.6 g. of the ketone just obtained (0.308 mole) were dissolved in 300 ml. of benzene, 123.5 g. of aluminium chloride was added in small doses, and the mixture was boiled under reflux for two hours.

The reaction mixture was hydrolysed by 500 g. ice; the precipitate extracted and taken up in a 10% aqueous caustic soda solution. The benzene phase obtained after hydrolysis is concentrated. The oil obtained is treated as above and the precipitate added to the other. The crystals were recrystallised in 50% ethanol 60 g. of product were obtained, melting at 142.

The reaction may also be eifected with excellent yields in methylene chloride.

(c) A solution of sodium ethylate was prepared by dissolving 3.45 g. of sodium (0.15 mole) in 200 ml. absolute ethanol. There was then added 31 g. of the preceding phenol (0.15 mole) then 25.8 g. ethyl chloroacetate. The mixture was refluxed for 15 hours. Hot extraction was carried out to eliminate the sodium chloride.

The ester precipitated on cooling the filtrate. The product was recrystallised once in isopropanol to give 29.4 g. of crystals melting at 58. The pure product melts at 6364.

The ester was dissolved in a solution of 300 ml. 95% ethanol and 9 ml. of 10 N caustic soda. The mixture was boiled under reflux for 30 minutes. The precipitate of the sodium salt of the acid which forms in the cold was extracted and taken up in warm water. The free acid was then precipitated in mineral acid medium. After recrystallisation in 50% ethanol, it melted at 148-9.

An alternative method is to start from an aqueous solution of phenate prepared by the action of caustic soda, add to it while boiling a slight excess of sodium monochloracetate, and, having maintained an alkaline pH for 3 hours refluxing, isolating the precipitate formed by hot filtration. The acid is freed from its salt by addition of a strong mineral acid to a hot aqueous solution, and extracted hot with dichloroethane. After recrystallisation in purified dichloroethane, the acid melts at 157.

The sodium salt of the acid melts at 270 and the potassium salt at 290. These melting points, determined by Maquenne block, have not been corrected.

The piperazine addition salt (prepared in ethanol with two molecules of acid per one piperazine) melts at 216. The N-methyl piperazine addition salt (prepared starting from the acid and the base in equimolecular proportions), melts at 140, while the N-methyl glucamine addition salt, also prepared with an aquimolecular proportion of acid and base, does not crystallise.

EXAMPLE 3 administered in the usual TABLE 1 Acute toxicity in mice LDsu intravenous LDm per os Code mgJkg-mie g./kg.mice

GE 3598 450 1. 5 CE 3624 225 1. 275 CE 3649- 580 2. 9

(II) TOLERANCE Administered in doses from 50 to 200 mg./ kg. via the digestive tract to lots of three dogs for 5 days, the products CE 3598, CE 3624 and CE 3649 gave rise to no symptoms which would indicate any injurious activity.

4 (III) PHARMACOLOGY (A) General Pharmacology No pharmacological activity other than that described herein has been observed.

Administered either orally or intravenously, the three compounds had practically no action in screening tests designed to reveal any activity such as analgesic, ant1-mfiam matory, hypoglycemiant, hypochloesterolemiant, antispasmodic, antichlolinergic, cardiovascular, psychotropic, etc.

However, in anaesthetised dogs, the injection of one or other of the three compounds at doses of from 10-50 mg./kg., produced a fall in tension, in part in agreement with the diuretic activity and in part with an action peculiar to this type of molecule.

(B) Diuretic Activity (a) In mice The three compounds CE 3598, CE 3624, CE 3649 can be shown to be diuretic at doses of from 150 mg./ kg. for the first. For example, for CE 3624, diuretic is doubled at 25 mg./ kg. and quintupled at 50 mg./kg., while for CE 3649, its activity is a quarter of that of CE 3624.

(b) In dogs (1) In dogs anaesthetized with mebubarbital (30 mg./ kg.), the diuretic action provoked by CE 3624 is extreme- ,ly substantial and precocious. The doses injected were of the order of 5-30 mg./kg. In most cases, diuresis was decupled for more than 2 hours.

As far as CE 3598 is concerned, in the case of an intravenous injection, a substantial diuretic action is provoked in the first 15 minutes, at weak doses of the order of 10 mg./kg. This increase in diuresis is still preceptible 2 hours after injection, the peak of activity being between 15 and 30 minutes. The size of the increase may reach 6 to 7 times, even 10 times, the base diuresis.

In the case of intraduodenal injection or administration per os, the active doses are relatively the same as by intravenous administration.

(2) In non-anaesthetized dogs: After hydration with 500 ml. physiological water and calculation of the diuresis for 2 hours, CE 3624, CE 3649 and CE 3598 were administered per as at doses of from 10 to mg./kg. In these conditions, diuresis was strongly increased.

For CE 3624 at 20 mg./kg., the diuresis was quintupled for 3 hours; the same result was obtained at 10 mg./kg. For CE 3649, at the same doses, the diuresis was only doubled. The doses of CE 3598 administered per os were 25, 50 and 100 mg./kg. The increase in diuresis was effective during the first hour, and still notable 3 hours after administration of the product.

The 4-(2-furyl keto) 2,3-dichloro phenoxy acetic acid and its salts, 4-(2-thienyl keto) 2,3-dichloro phenoxyacetic acid and 4-[2(5-methy1 thienyl) keto] 2,3-dichloro phenoxyacetic acid and their salts are useable in human and veterinary therapy as diuretics, in particular in all cases requiring the use of powerful diuretics. Their mode of operation, by inhibiting the reabsorption of sodium in the proximal tube and the ascending portion of Henles tube is of great interest in hydrosodic reactions and nephrotic oedemas.

These compounds can be used as active principles associated or not with other appropriate active principles, in the principal pharmaceutically suitable forms, such as tablets, capsules, suppositories and injectable solutions.

For per os administration, for suppositories, and for injectable solutions the dose can be from 0.050 to 1 g. of active product.

The compounds can be administered in daily doses varying from 100 to 1500 mg.; at these doses, they do not provoke any undesirable secondary phenomena; in particular, potassium loss is relatively weak.

Examples of typical formulations are as follows:

FORMULATION l.FOR TABLETS G. Active principle 0.500 Potato starch 0.020 Polyvinyl pyrrolidone 0.020 Maize starch 0.045 Talc 0.020 Magnesium stearate 0.015 FORMULATION 2.FOR INJECTABLE SOLUTIONS N-methyl piperazine salt of CE 3624 gm 0.500 Distilled water ml 2 We claim as our invention:

1. A phenoxyacetic acid compound selected from the class consisting of phenoxy acetic acids of the general formula wherein R signifies a group selected from the class consisting of 2-furyl keto, 2-thienyl keto, and 2(5-methyl thienyl) keto, alkali metal salts of a said acid, and addition salts of a said acid with a pharmaceutically acceptable base.

2. A phenoxyacetic compound according to claim 1 which is the addition salt of a said acid with a base selected from the class consisting of piperazine, N-methyl piperazine and N-methyl glucamine.

3. A compound selected from the class consisting of 4-(2-furyl keto) 2,3 dichloro phenoxyacetic acid, alkali metal salts thereof and addition salts thereof with a pharmaceutically acceptable base.

4. A phenoxyacetic acid compound selected from the class consisting of 4-(2-thienyl keto) 2,3 dichloro phenoxyacetic acid, alkali metal salts thereof and addition salts thereof with a pharmaceutically acceptable base.

5. A phenoxyacetic acid compound selected from the class consisting of 4-[2(5-methyl thieny1)keto] 2,3 dichloro phenoxyacetic acid, alkali metal salts thereof and addition salts thereof with a pharmaceutically acceptable base.

References Cited Fieser et al., Advanced Organic Chemistry (Reinhold, New York, 1962), pp. 628-35, 655-7 and 747-8.

Morrison et al., Organic Chemistry (Allyn and Bacon, Boston, 1959), p. 678.

HENRY R. J ILES, Primary Examiner C. M. S. J AISLE, Assistant Examiner US. Cl. X.R. 

